Abstract
We apply density functional and ionization potential equation of motion coupled cluster theories to investigate hole transport in graphitic carbon nitride (g-C3N4), an organic photocatalyst which drives water splitting and oxidative organic reactions. Calculations on small cationic model clusters suggest that the formation of two-center, three-electron bonds involving lone pair electrons on the nitrogen atoms of adjacent monomer units in g-C3N4 results in the localization of positive charge; reorganization energies for polaron hopping range from 1.3 to 2.1 eV depending on whether the material is fully condensed into a two-dimensional sheet or linearly polymerized. Similarly, the chemical character of the valence band maximum (VBM) is determined by the strength of the antibonding interaction between lone pair electrons on neighboring monomers; the fully condensed material has a VBM composed predominantly of nitrogen lone pair electrons, whereas the polymer exhibits a VBM of π character.
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